Ionizing Radiation Detector

ABSTRACT

The invention concerns an ionizing radiation detector comprising a housing containing:
         an avalanche photodiode in contact, through its photosensitive face, with the scintillator material via optical coupling,   a preamplifier of the electrical signal from the avalanche photodiode.
 
This detector is compact, portable, and very robust. It detects X-rays or gamma rays with excellent resolution, which can be less than 3% at 662 keV.

The invention concerns the field of detecting ionizing radiation, in particular X-rays or gamma rays, using a crystal scintillator.

Ionizing radiation (which includes ionizing particles such as in particular protons, neutrons, electrons, alpha particles, and X-rays or gamma rays) are usually detected using single-crystal scintillators that convert the incident radiation into light, which is then converted into an electrical signal using a photomultiplier. In the case of X-rays or gamma rays the scintillators used can be, in particular, made of doped single crystals of Nal, Csl or lanthanum halide. Lanthanum halide based crystals have been the subject of recent work such as that published under U.S. Pat. No. 7,067,815, U.S. Pat. No. 7,067,816, US2005/188914, US2006/104880, and US2007/241284. These crystals are promising in terms of luminous intensity and resolution, but require special precautions as a result of their hygroscopic character.

These detection systems are used, inter alia, in the field of medical imaging scanners, airport security scanners, and oil exploration. The conversion of the light emitted by the crystal into an electrical signal is generally effected by a photomultiplier. Photomultipliers are relatively restrictive due to their high-voltage power supply and are bulky and fragile as a result of the glass bulb they contain.

There is a need in particular for a system for detecting X-rays or gamma rays that is portable and mobile. Indeed, it is desired that certain people, specifically those assigned to security, should be easily able to detect this type of radiation by their mere presence. This need exists particularly in security and safety activities concerning ionizing radiation. This involves, for example, detecting and identifying illicit radioactive sources. These systems must detect X-rays or gamma rays and, preferably, be capable of identifying the nature of the radioisotope.

It is therefore useful to develop compact systems for detecting ionizing radiation, and more particularly X-rays or gamma rays. A system for detecting X-rays or gamma rays is elaborated in more detail below, it being understood that the principle of this system can be adapted to detect other types of ionizing radiation as soon as the scintillator and the input window are adapted to said targeted types of radiation. Such a compact detector must be as small as possible while preserving good detection properties, particularly as far as signal resolution and energy linearity (that is, the proportionality between the energy of the X-ray and gamma photons and the detector's response) are concerned. In particular, the photomultiplier usually used to convert the scintillator light into an electrical signal occupies a fairly large volume, of around 180 cm³, and it is desirable to be able to reduce this volume. In addition, photomultipliers work at high voltage and are sensitive to external magnetic fields, such as that of the Earth for example. Photodiodes are able to detect the light, but they generally produce noise that impairs resolution and the threshold of minimum detectable energy (typically 60 keV). The performance and the resolution obtained can be improved by cooling the photodiode. There are several types of photodiode: PN, PIN, avalanche photodiodes (in linear mode or Geiger mode), silicon drift detectors, etc.

The energy resolution of an ionizing radiation detector in fact determines its capacity to separate very close radiation energies. It is usually determined for a given detector, at a given energy, as the half-peak width of the peak considered over an energy spectrum obtained from this detector, normalized with respect to the peak centroid energy (see in particular G. F Knoll, “Radiation Detection and Measurement”, John Wiley and Sons, Inc., 2nd edition, p 114). The percentage resolution is the half-peak width of the photoelectric peak divided by the energy of this peak and multiplied by 100. In the following text, for all measurements carried out, the resolution is determined at 662 keV, the energy of the principal gamma emission of Cs 137.

The article by R. Scafè et al., Nuclear Instruments and Methods in Physics Research A 571 (2007) 355-357 teaches detection of the light emitted by a LaBr₃:Ce crystal by an avalanche photodiode. The crystal had a diameter of 12 mm and the photodiode an area of 5 mm×5 mm. The crystal was provided by Saint-Gobain and was encapsulated in an aluminum housing with a 5 mm thick glass window. The photodiode was outside this housing and received the light emitted by the crystal through the glass window. A fortiori the preamplifier was also outside the housing. The gamma radiation was received through a 0.5 mm thick aluminum window. The observed resolution was 7.3% for incident photons of 662 keV energy.

The article by K. S. Shah et al., IEEE Transactions on Nuclear Science, Vol. 51, No. 5, October 2004 compares the detection of light emitted by an LaBr₃ crystal doped with 0.5% Ce by an avalanche photodiode on the one hand and by a photomultiplier on the other. The avalanche photodiode was cooled to 250 K (or −23° C.). This article concludes that at ambient temperature photomultiplier detection would be chosen to obtain the highest resolution.

The article by C. P. Allier et al., Nuclear Instruments and Methods in Physics Research A 485 (2002) 547-550 reports on the detection of light emitted by a LaCl₃:Ce crystal by an avalanche photodiode working at a voltage of 1500-1700 volts. The photodiode was coupled to the crystal by means of a low viscosity silicon grease. Taking account of the hygroscopic character of the crystal used and this being an experimental system in a university environment, the assembly was necessarily carried out entirely in a glove box in an inert atmosphere, said glove box containing the radioactive source, the crystal and the photodiode. The reported resolution was 3.65% at 662 keV.

The article by C. P. Allier et al., 2000 IEEE Nuclear Science Symposium Conference Record & Medical Imaging Conference (2000: Lyon, France) teaches the detection of light emitted by a LaCl₃:Ce crystal by an avalanche photodiode working at a voltage of 1500-1700 volts. The photodiode was coupled to the crystal by means of an oil. Taking account of the hygroscopic character of the crystal used and this being an experimental system in a university environment, the assembly was necessarily carried out entirely in a glove box in an inert atmosphere, said glove box containing the radioactive source, the crystal and the photodiode. The reported resolution was 3.65% at 662 keV. Taking account of the small volume of the crystal (63 mm²), obtaining a spectrum for the radiation source requires a long duration of acquisition or a highly active source. A pinhole (small hole) allows the nonuniformity in the sensitivity of the photodiode to be factored out.

EP1435666 teaches a detector, in a housing, a scintillator whose light is focused onto an avalanche photodiode by means of a lens. It was observed that the distance of the photodiode from the scintillator, due to the multitude of materials (glass lens, air around the lens) between the scintillator and the photodiode, in fact leads to mediocre results in terms of resolution.

US 2005/0127300 teaches a scintillator made of polycrystalline ceramic (necessarily nontransparent) which surrounds a photodiode. Light losses are inevitable at the scintillator placed below the photodiode. This light loss necessarily causes poor resolution. Such an assembly is used, above all, to detect the presence of radiation without being able to identify it, as the recording of a source spectrum is impossible.

The possibility has now been found of producing a detection system at ambient temperature (without the need for a stabilization system or a cooling system) comprising an avalanche photodiode and leading to excellent resolution, which may be less than 3.5%, or even less than 3%, or even less than 2.9% at 662 keV. It must be understood that the more the resolution of a detection system is improved, the more difficult it is to improve it further. Thus with a lanthanum bromide based crystal, passing, for example, from a resolution of 3.0 to 2.9% is a very significant step forward.

The detector according to the invention in particular allows X-ray or gamma ray detection with excellent resolutions and with a very low detection threshold. This detection threshold can, specifically, be less than 15 keV, even less than 12 keV, or even less than 11 keV, measured with an americium 241 source. The detection threshold is given by the abscissa of the valley between the noise at low energy (to the left of the valley) and the source signal (generally americium 241). A detector which has a good detection threshold with one source will have a good detection threshold with another source.

The detection system is based on the compactness of its various components, all arranged in a sealed housing, with a minimum of material and of distance between its different elements. Indeed it has been observed that rigorous application of this principle leads to results that are noteworthy and surprising in terms of resolution and detection threshold. The invention thus concerns a sealed housing for the detection of ionizing radiations and in particular for the detection of X-rays and gamma rays, comprising a scintillator material (in particular a rare earth halide crystal when X-rays or gamma rays are targeted), an avalanche photodiode coupled to the scintillator material by optical coupling, and a preamplifier for amplifying the electrical signal from said photodiode. It appears that the compactness of this system, by reducing the distance between its various components, is one of the elements allowing the noise that usually impairs the resolution and detection threshold to be reduced to a minimum. Reducing the distance reduces noise. Encapsulating the components in the metal housing and adding a metal plate between the photodiode and the preamplifier also allows noise to be reduced by providing electromagnetic shielding. With a crystal made of LaBr₃:Ce (cerium doped lanthanum bromide) provided with a light guide, the detection threshold is around 40 keV in a nonencapsulated system without shielding. It is reduced by 20 keV thanks to the encapsulation. These measurements are found in Table 1, in rows 2 and 10. The importance of the quality of encapsulation and of the shielding will therefore be understood. According to the invention, in an optimized system, the detection threshold can even be less than 10 keV (row 14 of Table 1).

The housing according to the invention is small in size, it being possible for its external volume to be less than 1000 cm³ and even less than 500 cm³, 300 cm³, 100 cm³ or 60 cm³. The inventors have even already produced a housing with a volume as low as 50.4 cm³ and including a parallelepipedal scintillator with the dimensions 9×9×20 mm³. A smaller crystal would allow the volume of the housing to be reduced even more, but said crystal would stop less radiation and the sensitivity of the detector would be lower.

The scintillator material can have a volume between 1 and 50000 mm³. When the rays to be detected are low energy, low scintillator volumes can suffice. For higher energies, larger volumes are preferable. Specifically for the detection of X-rays or gamma rays, the scintillator preferably has a volume larger than 1000 mm³ and even larger than 1300 mm³. Its volume is generally less than 10000 mm³ and even less than 5000 mm³. Thus the housing according to the invention can even be smaller in size than a simple photomultiplier. The size of the scintillator located in the direction of incident radiations is chosen in order to absorb the maximum of radiation. For example, the previously mentioned scintillator has a thickness of 20 mm, which allows 100% of photons with an energy of 122 keV emitted by a Co⁵⁷ source to be absorbed, and around 53% of photons with an energy of 662 keV emitted by a Cs¹³⁷ source. The higher the proportion of absorbed radiation, the less active the source must be in order to be identified and the shorter the acquisition of the spectrum.

The detector according to the invention is light. The mass of the detector previously mentioned, containing the 9×9×20 mm³ scintillator as well as the electronics with electrical connections, is around 60 grams. Thus the detector according to the invention can weigh less than 100 grams. Finally the detector can be portable (it fits in the hand, in a pocket, etc.), resistant to impacts and vibrations, resistant to bad weather, and resistant to extreme temperatures (−20 to +50° C.).

The housing is a container, preferably comprising a metal, and it must allow the types of radiation to be detected to pass through to the scintillator material. It must also be opaque to visible light and preferably provide shielding from electromagnetic waves of all kinds (mobile phone, radio waves, television waves etc.) that are capable of interfering with electronic circuits. The housing can therefore be at least partly, or totally, made of a metal that allows the radiation to be detected to pass, such as aluminum (it should be noted that the term “aluminum” also covers aluminum alloys compatible with the application, that is alloys permeable to the intreated radiation and especially to X-rays and gamma rays). Notably, one face of the housing can serve more particularly for receiving radiation. Thus the face of the housing acting as a window may be a little thinner than the other walls of the housing. The housing can also be made of a plastic (a polymer material such as, for example, PE, PP, PS) and be covered with a thin layer or foil of metal such as aluminum. For example, the housing may be a parallelepiped made completely of aluminum (or aluminum alloy) and have one face thinner than the others. In the case of detecting X-rays or gamma rays, by way of example, this face may be made of aluminum of 0.5 mm thickness, the other walls possibly being made for example of aluminum of 1 mm thickness. For the detection of ionizing particles, an aluminum window must be much thinner (of the aluminum “foil” type).

In the case of detecting X-rays or gamma rays the housing contains the scintillator material comprising a rare earth halide. This is generally of the single-crystal type and comprises a rare earth halide, essentially a chloride, bromide, iodide or fluoride, generally of formula A_(n)Ln_(p)X_(3p+n) in which Ln represents one or more rare earths, X represents one or more halogen atoms chosen from F, Cl, Br or I, and A represents one or more alkali metals such as K, Li, Na, Rb or Cs, n and p representing values such that:

-   -   n, which can be zero, is less than or equal to 3p     -   p is greater than or equal to 1.

The rare earths (in the form of halides) concerned are those in column 3 of the Periodic Table, including Sc, Y, La, and the lanthanides from Ce to Lu. More particularly concerned are the halides of Y, La, Gd and Lu, especially doped with Ce or Pr (the term “dopant” here refers to a rare earth that is generally a minor component in molar terms, replacing one or more rare earths that are generally major components in molar terms, the minor and major components being included under the abbreviation Ln).

More particularly concerned are especially materials of formula A_(n)Ln_(p−x)Ln′_(x)X_((3p+n)) in which A, X, n and p have the previously given meanings, Ln being chosen from Y, La, Gd and Lu or a mixture of these elements, Ln′ being a dopant such as Ce or Pr, and x is greater than or equal to 0.01p and less than p, and ranges more generally from 0.01 p to 0.9p. Especially of interest within the context of the invention are materials combining the following characteristics:

-   -   A chosen from Li, Na and Cs,     -   Ln chosen from Y, La, Gd, Lu or a mixture of these rare earths,         Ln being more particularly La,     -   Ln′ being Ce,     -   X chosen from F, Cl, Br, I or a mixture of several of these         halogens, especially a mixture of Cl and Br, or a mixture of Br         and I.

A scintillator material particularly suited to the detection of X-rays or gamma rays is a single crystal comprising LaX₃ doped with cerium (Ce), where X represents Br, Cl or I, with halide mixtures, especially chloride/bromide mixtures, being possible. When speaking of a cerium-doped rare earth halide, a person skilled in the art will immediately know that the cerium is in halide form, that is to say that the rare earth halide contains a cerium halide. The following single crystals, especially, are particularly suited:

-   -   LaBr₃ doped with 1 to 30 mol % of CeBr₃;     -   LaCl₃ doped with 1 to 30 mol % of CeCl₃;     -   yLaBr₃+(1−y)CeBr₃ with y≧0.

The scintillator material can, in particular, be cylindrical or parallelepipedal and be larger along one axis. This axis is then perpendicular to the plane of the photodiode. The scintillator material is placed in the housing in immediate proximity to that wall of the housing acting as window. A sheet of a shock-absorbing material may be placed between the crystal and the wall of the housing.

The scintillator material is generally covered with a light reflector. This reflector preferably covers all the sides of the scintillator material, apart from the area through which the light emitted by the scintillator must pass to reach the photodiode. The light reflector may be made of PTFE (polytetrafluoroethylene). It can therefore be a strip of PTFE with which the scintillator material is surrounded. Before being covered with the light reflector, the external faces of the scintillator material are preferably roughened (or frosted) with an abrasive material such as abrasive paper (especially 400 grit). The roughness thus given to the surface increases the light flux received by the photodetector.

The housing contains an avalanche photodiode. This photodiode is in contact with the scintillator material via an optical coupling material. This might be a silicon grease (polysiloxane) or any other transparent, nonadhesive material, but this optical coupling is preferably an epoxy adhesive. Once the epoxy adhesive has hardened, the photodiode and the crystal are joined together. The optical coupling has a refractive index between that of the scintillator material and that of the avalanche photodiode. When the optical coupling is solid (in the case of an epoxy adhesive) it is preferably chosen such that its thermal expansion coefficient is between that of the avalanche photodiode and that of the scintillator material. It can also be relatively flexible. In this way the coupling better absorbs the differences in thermal expansion between the two materials that it links. This reduces the risks of fracturing the crystal in the case of excessive heating.

The thickness of the optical coupling is preferably less than 2 mm and even less than 1 mm, and more preferably still less than 0.6 mm. For the person skilled in the art the term “optical coupling” excludes a vacuum and gases such as air. An optical coupling is necessarily liquid (which includes “greasy”) or solid.

The avalanche photodiode is generally a flat component with two main faces. It is one of these main faces that is in contact with a plane face of the scintillator material via the optical coupling. The face of the scintillator material in contact with the photodiode (contact face of the scintillator material) is preferably inscribed in that face of the photodiode with which it is in contact (contact face of the photodiode). Consideration is taken here of the light-sensitive surface of the photodiode (or the photosensitive face). In fact the photodiode generally comprises a light-sensitive area surrounded by a dead area (insensitive to light) corresponding to the encapsulation material of the photodiode. It should therefore be borne in mind that the expression “contact face of the photodiode” or “contact face area of the photodiode” refers to the sensitive area of the photodiode.

The scintillator material is placed completely opposite the sensitive face of the photodiode. This means that the scintillator material does not surround the photodiode but is completely contained in the half space delimited by the plane passing through the sensitive face of the photodiode and facing (or opposite) said sensitive face. Said half space containing the scintillator material does not therefore contain the photodiode.

The contact face of the scintillator material and the contact face of the photodiode preferably have the same shape (both are square for example), the contact face of the scintillator material preferably being a little smaller (in a homothetic manner) than the contact face of the photodiode. Preferably, each point on the edge of the contact face of the scintillator material is inside the (sensitive) contact face of the photodiode, and at a distance of between 0.1 and 3 mm, preferably of 0.2 to 0.7 mm, from the edge of the contact face of the photodiode.

The contact face area of the scintillator material is preferably less than 1.5 times, and even less than 1.2 times or even less than 1 times the contact face area of the avalanche photodiode. Saying that the contact face area of the scintillator material is less than 1.5 times the contact face area of the photodiode means that if the contact face area of the photodiode is S, the contact face area of the scintillator material is less than 1.5 multiplied by S. The contact face area of the scintillator material can therefore be greater than the contact face area of the photodiode. However, the contact face area of the scintillator material preferably ranges from 0.8 to 1 times the contact face area of the avalanche photodiode. By way of example, a photodiode with a sensitive surface area of 0.2 cm² is compared with a photodiode of 1 cm² in rows 2 and 12 of Table 1. It can be seen that for the 10×10×10 mm³ crystal provided with a glass window performance is very different, going from a resolution of more than 8.5% with the smallest photodiode to almost 3.0% with the largest.

The invention thus also concerns the detection system comprising the scintillator material and the avalanche photodiode, preferably respecting the contact face data just given, even for a noncompact system. A compact system is nonetheless preferred.

The avalanche photodiode preferably works at a voltage of less than 1050 volts, and more preferably still at a voltage of less than 450 volts.

The photodiode generally has two electrical connectors. These two connectors are preferably soldered directly to a charge amplifier called a preamplifier, the components of which are located on a printed circuit that is also incorporated within the housing according to the invention. The preamplifier might, in particular, have the following characteristics: power supply +/−12 V or +24/0 V, gain of 0.1 V/pC to 10 V/pC. An electromagnetic shielding element such as a copper or brass plate, electrically connected to the housing and to ground, is preferably placed between the avalanche photodiode and the preamplifier. The photodiode connectors, insulated by polymer sheaths or by insulating adhesive, pass through the shielding element via orifices. Note that the electromagnetic shielding is an obstacle to electromagnetic waves of all kinds (mobile phone, radio waves, television waves etc.) that are capable of interfering with electronic circuits. The metal housing (which can be of aluminum) contributes to this shielding.

The photodetector used within the context of the present invention is an avalanche photodiode, this term covering a simple individual photodiode, but also an array of avalanche photodiodes, that is a collection of individual avalanche photodiodes grouped on one face of the crystal and the signals of which are summed. This collection therefore includes a dead area (insensitive to light) around the array, but also in general between the individual photodiodes. The characteristics given above for the relation between the contact areas between the avalanche photodiode and the scintillator material remain valid and it is the cumulative area of the light-sensitive contact surfaces of the linked avalanche photodiodes that is taken into consideration. However, in the case of an array of avalanche photodiodes, the surface of the contact face of the scintillator material may be larger than the cumulative (light-sensitive) contact surface of the avalanche photodiodes, due to the existence of dead areas between the individual photodiodes in the array. The silicon PM can be cited as an example of a photodetector consisting of an array of avalanche photodiodes in Geiger mode.

According to the invention it is not necessary to collimate the incident radiation. Collimation, for example by surrounding the source with a pierced absorbing material, provides a fine beam of radiation which, as it irradiates only a particular point of the detector, allows inhomogeneities in the crystal or in the photodiode to be factored out. It turns out that the quality of the combination of the scintillator, its reflector, the optical coupling and the photodiode allows excellent performance to be obtained without using a collimation.

The housing according to the invention can have an axis passing through the centre of gravity of the scintillator material and the centre of gravity of the radiation entrance window. Moving along this axis, starting with the entrance window, the light reflector, the scintillator material, the optical coupling, the photodiode, the shielding and the preamplifier are successively encountered. The photodiode, the shielding (where this is a plate) and the preamplifier printed circuit, in particular, can be perpendicular to this axis.

The entrance window can also be lateral, that is parallel to an axis of the housing. If the housing is a parallelepiped, five of its faces (the four lateral ones and the front face) can constitute the entrance window.

The compactness of the detector according to the invention is characterized especially by the absence of a light guide between the crystal and the avalanche photodiode (apart from the thin layer of optical coupling, in particular of the epoxy adhesive type, which can have a thickness of less than 0.6 mm, along with a possible protection layer for the surface of the avalanche photodiode), a short distance between the preamplifier and the scintillator material, such that the two closest points, one of the preamplifier and the other of the scintillator material, can generally be less than 2 cm apart.

According to the prior art, when they must operate in an environment at ambient temperature, the photodiodes are often cooled below 0° C. The performance of the detector according to the invention is such that a temperature stabilization system (cooling or heating) is not necessary. Cooling systems such as a Peltier module, a heat sink, a fan, or the circulation of a coolant increase the size requirement, the mass or the electrical consumption. However, in the case in which the detector may not be used at constant temperature, the addition of a thermal insulation system or even an active temperature stabilization system is a possible option as the gain of an avalanche photodiode varies with temperature. A possible design of a detector equipped with a temperature stabilization system is the following:

-   -   the (first) thermally conductive housing containing, as         previously, the scintillator material, the avalanche photodiode         and the preamplifier,     -   thermal insulation around this housing (for example: expanded         polystyrene, or a vacuum, or air),     -   an outer thermally conductive casing (or second housing)         containing the first housing covered by the thermal insulation,     -   a Peltier module (operating on the principle of a thermoelectric         effect) in thermal contact via one of its faces with the first         housing, its other face being in thermal contact with the outer         casing,     -   a heat sink fixed to the outer casing,     -   a fan mounted on top of the heat sink.

For the case in which this detector must contend with hot ambient temperatures (such as higher than 25° C.), the cold side of the Peltier module is in thermal contact with the inner housing, while the hot side of the Peltier module is in thermal contact with the outer casing. For the case in which this detector must contend with cold ambient temperatures (such as lower than 20° C.), the hot side of the Peltier module is in thermal contact with the inner housing, while the cold side of the Peltier module is in thermal contact with the outer casing.

The expression “thermal contact” used with regard to the Peltier module means that it is directly touching the housing (or casing) with which it is in thermal contact or alternatively that an intermediate part (generally a metal part) that conducts heat well is placed between said Peltier module and said housing (or said casing).

The addition of a temperature probe such as a PT1000 thermistor (marketed by the company Correge) enables the effectiveness of the stabilization provided to be checked and allows automatic control of the system so as to regulate the temperature inside the housing (first housing) when the outside ambient temperature (outside the outer casing) varies.

The outer casing (or second housing) is made of a material that conducts heat well and is permeable to the intreated radiation and especially to X-rays and gamma rays. It may therefore be made at least partly, or totally, of a metal allowing through the radiation to be detected, such as made of aluminum (it should be noted that the term “aluminum” also covers aluminum alloys that are compatible with the application, i.e. are permeable to the intreated radiation and especially to X-rays and gamma rays). In particular, one face of the casing may more particularly function as a window for receiving radiation. Thus, the face serving as a window of the casing may be a little thinner than the other walls of said casing. The window face of the outer casing is opposite the “window” face of the (first) inner housing. The casing may, for example, be a parallelepiped completely made of aluminum (or aluminum alloy) and include one face (window face) thinner than the others. For the case of detection of X-rays or gamma rays, by way of example, this face may be of 0.5 mm thick aluminum, the other walls possibly being, for example, of 1 mm thick aluminum.

The inventors have, for example, developed a detector (FIG. 5) of outer size 7.2×7.0×5.2=262 cm³ and, in an outside environment at 50° C., a stabilized temperature of around 20° C. in the inner housing (first housing) has been obtained. The Peltier module was the Supercool PE-127-08-15 brand. The size of the outer casing, especially the thickness of the insulator, depends on the outside temperature to be compensated for.

Thus the invention also relates to a detector equipped with a temperature stabilization system. In particular, as explained above, the housing may be placed in a casing, a Peltier module being placed between said housing and said casing.

Although the detector according to the invention exhibits good performance between −20° and +50° C. without a temperature stabilization system, it is preferable to provide such a system in the case of significant fluctuation in the ambient temperature or in the case of the temperature being above 25° C. or below −20° C. on a permanent basis.

The invention also concerns a method of detecting ionizing radiation such as X-rays or gamma rays using the detector according to the invention.

FIG. 1 shows a compact detector according to the invention. It has an axis AA′.

The reference numbers have the following meanings: 1: ground wire soldered into the hole in the closure plate 2: aluminum housing 3: preamplifier 4: brass plate (shielding) 5: avalanche photodiode S-8664-1010 6: optical coupling 7: PTFE covering (light reflector) 8: single-crystal scintillator, of which the face on the photodiode side has been polished and the other faces have been roughened 9: 0.5 mm thick aluminum entrance window 10: signal connector 11: low voltage connector 12: high voltage connector 13: insulator The other figures outside the housing are the dimensions in mm.

FIG. 2 illustrates the linearity, that is the proportionality between the energy of the incident X-ray or gamma-ray photons and the response of the detection system of the compact detector according to an example of the invention.

FIG. 3 shows the spectrum of an Am 241 source measured using a compact detection system according to the invention. The detection threshold is indicated by the letter S. It is excellent as it is around 10 keV.

FIG. 4 shows the spectrum of a Cs 137 source (energy of incident photons of 662 keV) measured by a compact system according to the invention.

FIG. 5 shows a detector according to the invention equipped with a temperature stabilization system. An outer casing 20 made of aluminum contains the housing 21 which is also made of aluminum, said housing containing the scintillator material and the preamplifier as for FIG. 1. A Peltier module 22 is in thermal contact with the housing 21 on the side of its cold side and in thermal contact with the outer casing 20 on the side of its hot side. The thermal contact with the outer casing is made via a spacer made of copper that conducts heat well. A heat sink (radiator) 24 is fixed on the outside of the casing and a fan 25 helps remove the heat. The duct 26 contains the electric power wires for the fan 25. The electric wires have not been shown inside the casing in the interest of clarity. Overall, the device is electrically connected to the outside via the connectors 27. The largest dimension of the outer casing was here 72 mm. Thermal insulation is placed between the outer casing and the housing containing the photodiode and the scintillator material. A thermistor (28) is placed inside the inner housing in order to control the temperature. Wires (not shown) coming from this thermistor as connected to a connector 27.

EXAMPLES

Single crystals of the following were used as scintillator material:

CsI doped with 0.8 mol % of TI denoted by CsI NaI doped with some TI denoted by NaI LaCl₃ doped with 10 mol % of CeCl₃ denoted by LaCl LaBr₃ doped with 5 mol % of CeBr₃ denoted by LaBr These could have the following forms:

cylindrical: Diameter height 25.4 mm 25.4 mm denoted by 25 × 25 12.8 mm 12.8 mm denoted by 13 × 13   6 mm   6 mm denoted by 6 × 6

parallelepipedal: Contact face height 10 mm × 10 mm 10 mm denoted by 10 × 10 × 10 9 mm × 9 mm 20 mm denoted by 9 × 9 × 20

The energy of the incident rays was 662 keV. The gamma radiation was not collimated. The ambient temperature was 23° C.±2° C. The avalanche photodiode (denoted by APD in Table 1) was a Hamamatsu S8664-1010. The photodiode PIN was a Hamamatsu S3590-08. The preamplifier was a Hamamatsu H4083.

The results are gathered in Table 1. The result in the last row illustrates the excellence of a compact system, that is one consisting of a housing that integrates the detector material, the avalanche photodiode and a preamplifier at a short distance from one another.

TABLE 1 Single-crystal Photodiode Detection scintillator Light area threshold Resolution Type Form guide Shielding Compactness Photodiode (cm²) (keV) at 662 keV LaBr 13 × 13 5 mm NO NO APD 1 20 4.0 glass LaBr 10 × 10 × 10 1 mm NO NO APD 1 19 3.0 glass LaBr 6 × 6 3 mm NO NO APD 1 20 3.1 glass LaBr 13 × 13 5 mm NO NO PIN 1 270 13.8 glass LaBr 12 × 6 Glass NO NO PIN 1 120 12.6 LaBr 6 × 6 3 mm NO NO PIN 1 100 11.3 glass CsI 6 × 6 3 mm NO NO APD 1 30 5.6 glass NaI 10 × 10 × 10 1 mm NO NO APD 1 23 6.4 glass LaCl 13 × 13 5 mm NO NO PIN 1 Not glass calculable LaBr 10 × 10 × 10 1 mm NO NO APD 1 41 3.2 glass LaBr 6 × 6 3 mm YES NO APD 0.2 8.4 glass LaBr 10 × 10 × 10 1 mm YES NO APD 0.2 8.7 glass LaBr 25 × 25 5 mm NO NO APD 1 66 5.0 glass LaBr 9 × 9 × 20 <0.5 mm   YES YES APD 1 10 2.8 epoxy adhesive

FIG. 2 illustrates the good linearity of the system, that is the proportionality between the energy of the incident X-ray or gamma-ray photons (plotted on the x-axis) and the response of the detection system (photoelectric peak value, plotted on the y-axis). It is evaluated by measuring the photoelectric peak value for gamma rays incident at 1332 keV (Co 60), 1173 keV (Co 60), 662 keV (Cs 137), 122 keV (Co 57) and 60 keV (Am 241). Note the absence of a lack of nonlinearity.

FIG. 3 shows the spectrum of an Am 241 source measured using the compact detection system according to the invention. It can be seen that the detection threshold is 10 keV, which is an extremely good performance. This is the value on the x-axis of the minimum on the left of the curve, between the noise to the left of this minimum and the source signal. The energy of the incident photons is 60 keV. The dimensions of the crystal are 9×9×20 mm.

FIG. 4 shows the spectrum of a Cs 137 source (incident photon energy of 662 keV). The resolution (half-peak width divided by the energy) is 2.8%. 

1. Ionizing radiation detector comprising a housing containing: a scintillator material, an avalanche photodiode in contact, through its photosensitive face, with the scintillator material via optical coupling, a preamplifier of the electrical signal from the avalanche photodiode.
 2. Detector according to the previous claim, characterized in that the scintillator material is covered with a light reflector.
 3. Detector according to one of the preceding claims, characterized in that the scintillator material is a rare-earth halide single crystal.
 4. Detector according to the preceding claim, characterized in that the single crystal is a cerium doped lanthanum bromide.
 5. Detector according to one of the preceding claims, characterized in that the volume of the housing is less than 300 cm³.
 6. Detector according to the preceding claim, characterized in that the volume of the housing is less than 60 cm³.
 7. Detector according to one of the preceding claims, characterized in that the scintillator material has a volume ranging from 1000 to 10000 mm³.
 8. Detector according to one of the preceding claims, characterized in that the housing comprises a metal.
 9. Detector according to one of the preceding claims, characterized in that the thickness of the optical coupling is less than 1 mm.
 10. Detector according to one of the preceding claims, characterized in that the optical coupling is an epoxy adhesive.
 11. Detector according to one of the preceding claims, characterized in that the refractive index of the optical coupling is between that of the scintillator material and that of the avalanche photodiode.
 12. Detector according to one of the preceding claims, characterized in that the thermal expansion coefficient of the optical coupling is between that of the scintillator material and that of the avalanche photodiode.
 13. Detector according to one of the preceding claims, characterized in that the scintillator material does not surround the photodiode but is completely contained in the half space delimited by the plane passing through the photosensitive face of the photodiode and not containing said photodiode.
 14. Detector according to one of the preceding claims, characterized in that the contact face area of the scintillator material is less than 1.5, and preferably less than 1.2 times, and even more preferably less than 1 times the contact face area of the avalanche photodiode.
 15. Detector according to the preceding claim, characterized in that the contact face area of the scintillator material is from 0.8 to 1 times the contact face area of the avalanche photodiode.
 16. Detector according to one of the preceding claims, characterized in that the contact face of the scintillator material and the contact face of the photodiode have the same form.
 17. Detector according to one of the preceding claims, characterized in that the contact face of the scintillator material is inscribed in the contact face of the avalanche photodiode.
 18. Detector according to one of the preceding claims, characterized in that every point of the edge of the contact face of the scintillator material is inside the contact face of the photodiode and at a distance of between 0.1 and 3 mm, and preferably between 0.2 and 0.7 mm, from the edge of the photodiode.
 19. Detector according to one of the preceding claims, characterized in that the avalanche photodiode works at a voltage of less than 450 volts.
 20. Detector according to one of the preceding claims, characterized in that there is an electromagnetic shielding element between the avalanche photodiode and the preamplifier.
 21. Detector according to one of the preceding claims, characterized in that the two closest points, one of the preamplifier and the other of the scintillator material, are less than 2 cm apart.
 22. Detector according to one of the preceding claims, characterized in that its resolution at 662 keV is less than 3.5% and even less than 3%.
 23. Detector according to the preceding claim, characterized in that its resolution at 662 keV is less than 2.9%.
 24. Detector according to one of the preceding claims, characterized in that the detection threshold measured with an americium 241 source is less than 15 keV and preferably less than 12 keV.
 25. Detector according to the preceding claim, characterized in that the detection threshold measured with an americium 241 source is less than 11 keV.
 26. Detector according to one of the preceding claims, characterized in that the preamplifier gain is between 0.1V/pC and 10 V/pC.
 27. Detector according to one of the preceding claims, characterized in that it does not comprise a cooling system.
 28. Detector according to one of the preceding claims, characterized in that it comprises a temperature stabilization system, the housing is placed in a casing, a Peltier module being placed between said housing and said casing.
 29. Method of detecting X-rays or gamma rays using the detector of one of the preceding claims.
 30. Method according to the preceding claim, without collimation of the radiation. 